Bed system with device charging storage pockets

This application claims priority to U.S. Provisional Application Ser. No. 63/295,194, filed on Dec. 30, 2021, the disclosure of which is incorporated by reference in its entirety.

This document describes devices, systems, and methods generally related to a bed system with storage pockets having device charging capabilities.

In general, a bed is a piece of furniture used as a location to sleep or relax. Many modern beds include a soft mattress on a bed frame. The mattress may include springs, foam material, and/or an air chamber to support the weight of one or more occupants.

The document generally relates to a bed system having storage pockets with device charging capabilities. More specifically, a foundation of the bed system can include side rails. Each of the side rails can include a storage pocket. The storage pockets can be positioned at locations along the side rails that are easy to reach by a user of the bed system, regardless of whether the user is laying flat or elevated to a variety of sleeping and/or reading positions. The storage pockets can be sized to hold items such as magazines, books, newspapers, laptops, and/or tablets. The storage pockets can also be sized to hold mobile devices, such as smartphones, cellphones, and wearable devices.

The storage pockets can include device charging capabilities. For example, a storage pocket can include one or more wired charging ports, such as USB and USB-C charging ports. The user can then connect their mobile device with a cable to one of the charging ports. Power for charging the devices can be provided via a power supply of the bed system, which can be plugged into an external power source, such as a wall outlet.

In some implementations, the storage pockets can include wireless charging capabilities. For example, an induction charger can be integrated into each of the side rails at a location parallel to a portion of each of the storage pockets. When the user places their mobile device inside one of the pockets, the mobile device can be wirelessly charged via the induction charger.

In yet some implementations, each of the storage pockets can include an additional pocket. The additional pocket can be smaller in dimensions than the storage pocket and can be positioned inside the storage pocket. The additional pocket can be configured to contain mobile devices, or devices up to certain dimensions/size. The induction charger described herein can be integrated into the side rail at a location parallel to a midpoint of the additional pocket. Therefore, when the user places their mobile device inside the additional pocket, the mobile device can be wirelessly charged via the induction charger.

One or more embodiments described herein can include a bed system including a foundation having a first side rail and a second side rail, the first side rail opposite the second side rail, and a pocket integrated into an exterior side of the first side rail.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, the bed system can also include a second pocket integrated into the second side rail. The bed system can include a mattress supported by the foundation. The pocket can be integrated into the first side rail at a distance from a head section of the mattress that is less than a distance from a foot section of the mattress. The pocket can include an inner pocket, the inner pocket being smaller than the pocket and positioned inside the first pocket. The inner pocket can be positioned at a lateral edge of the pocket and can extend a distance towards a midpoint of the pocket.

In some implementations, the pocket further can include a charging port housing and a charging port supported by the charging port housing. The bed system can also include a charging port housing positioned adjacent to the inner pocket. The bed system can include a charging port mounted in the inner pocket adjacent an inner surface of the inner pocket. The bed system can include a charging port housing positioned inside the inner pocket. The charging port housing can be positioned along an edge of the inner pocket that is proximate a midpoint of the pocket. The charging port can be a USB port, and the pocket further can include a USB-C port. The bed system further can include a power supply. The USB port and the USB-C port can be in wired communication with the power supply to receive power for charging a user device placed in the pocket. The power supply can wiredly connect to an outlet in a sleep environment, the power supply can be configured to provide power to components of the bed system.

The first side rail can include a wireless charger and a transmitter integrated therein for providing induction charging to a user device placed inside the pocket. The wireless charger and the transmitter can be integrated into a structure of the first side rail at a location opposite the pocket.

In some implementations, the bed system can include an induction charger integrated into a structure of the first side rail. The induction charger can be integrated into the structure of the first side rail at a location parallel a midpoint of the pocket, and the induction charger can be configured to wirelessly charge a user device placed inside the pocket. The induction charger can provide 5-15 W of output. The pocket can have a width within a range of 250-600 mm.

The pocket can be made of a same material as the first side rail. Moreover, the inner pocket can be made of a different material than at least one of the first side rail and the pocket. The inner pocket can be made of a same material as at least one of the first side rail and the pocket. The inner pocket can have a width within a range of 3-10 inches. The inner pocket can have a tolerance of ⅛ inch in length, ⅛ inch in width, and ⅛ inch in height.

One or more embodiments described herein can include a bed system including a foundation having a first side rail and a second side rail, a first pocket integrated into an exterior side of the first side rail, and a second pocket integrated into the exterior side of the first side rail and positioned inside the first pocket.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, the second pocket can be smaller than the first pocket. The second pocket can be positioned at a lateral edge of the first pocket and can extend a distance towards a midpoint of the first pocket. The first pocket further can include a charging port housing and a charging port supported by the charging port housing. The charging port housing can be positioned adjacent to the second pocket. The charging port can be mounted in the second pocket adjacent an inner surface of the second pocket. The charging port housing can be positioned along an edge of the second pocket that can be proximate a midpoint of the first pocket. The first side rail can include a wireless charger and a transmitter integrated therein for providing induction charging to a user device placed inside at least one of the first pocket and the second pocket. Moreover, the wireless charger and the transmitter can be integrated into a structure of the first side rail at a location opposite a midpoint of at least one of the first pocket and the second pocket.

One or more embodiments described herein can include a bed system including a foundation having a first side rail and a second side rail, and a pocket integrated into an exterior side of the first side rail having wired charging capabilities for a user device placed therein.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, the pocket can include a charging port housing and a charging port supported by the charging port housing. The charging port can be a USB port, and the pocket further can include a USB-C port. The bed system can also include a power supply, and the USB port and the USB-C port can be in wired communication with the power supply to receive power for charging a user device placed in the pocket. The bed system can include a second pocket integrated into an exterior side of the second side rail having wired charging capabilities for a second user device placed therein.

One or more embodiments described herein can also include a bed system including a foundation having a first side rail and a second side rail, and a pocket integrated into an exterior side of the first side rail having inductive charging capabilities for a user device placed therein.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, the first side rail can include a wireless charger and a transmitter integrated therein for providing induction charging to a user device placed inside the pocket. The wireless charger and the transmitter can be integrated into a structure of the first side rail at a location opposite the pocket. The bed system can also include an induction charger integrated into a structure of the first side rail. The induction charger can be integrated into the structure of the first side rail at a location parallel a midpoint of the pocket. The induction charger can be configured to wirelessly charge a user device placed inside the pocket. The bed system can also include a second pocket integrated into an exterior side of the second rail having inductive charging capabilities for a second user device placed therein.

One or more embodiments described herein can also include a bed system including a foundation having a first side rail and a second side rail, a pocket integrated into an exterior side of the first side rail having charging capabilities for a user device placed therein, and a power supply that can be configured to provide power to components of the bed system, the power supply being in wired communication with an external power source.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, the first side rail can include a wireless charger and a transmitter integrated therein for providing induction charging to a user device placed inside the pocket. The wireless charger and the transmitter can be integrated into a structure of the first side rail at a location opposite the pocket. The bed system can also include an induction charger that can be integrated into a structure of the first side rail. The induction charger can be integrated into the structure of the first side rail at a location parallel a midpoint of the pocket, and the induction charger can be configured to wirelessly charge a user device placed inside the pocket. The pocket further can include a charging port housing and a charging port supported by the charging port housing that can receive power from the power supply. The charging port can be a USB port and the pocket further can include a USB-C port. The USB port and the USB-C port can be in wired communication with the power supply to receive power for charging a user device placed in the pocket. The induction charger can be placed inside a padded cavity in the structure of the first side rail and an upholstery fabric material of the first side rail can cover the induction charger inside the padded cavity.

One or more embodiments described herein can include a bed system including a foundation having first and second side rails, and first and second pockets integrated into external sides of the first and second side rails, respectively.

In some implementations, the embodiments described herein can optionally include one or more of the following features. For example, each of the first and second pockets can have a width within a range of 4-20 inches. Each of the first and second pockets can be made of a same material as the first and second side rails, respectively. Each of the first and second pockets can be made of a different material than the first and second side rails, respectively. Each of the first and second pockets can be closer to a head end of the foundation than a foot end of the foundation.

The devices, system, and techniques described herein may provide one or more of the following advantages. For example, the integrated charging and storage pockets can provide ease of access to devices and other items while the user is in bed. Nonintrusive design of the pockets integrated into side rails of the foundation can make it easy for the user to reach, regardless of whether the user is laying down or in another position in the bed. The pockets also reduce visible nightstand clutter, since the user can now store their items in the pockets rather than on the nightstand(s). Moreover, the pockets can be designed as left-sided and right-sided pockets for integration into respective left and right side rails of the foundation. Thus, regardless of which side of the bed the user is on, the user can easily reach one or more of the pockets.

As another example, the pockets can provide for convenient device charging capabilities. The disclosed techniques can offer a complete charging solution that gives the user multiple charging options right from the bed. The user can charge devices using either USB or USB-C charging ports that are integrated into the pockets. The user can also charge devices using induction charging, which is especially beneficial of the user does not have a charging cable at hand to plug into one of the charging ports. The user can charge multiple devices at a time. The user can also charge their device(s) while the user is sleeping or otherwise in the bed without having to get up and plug the device(s) into wall outlets of a surrounding environment.

The disclosed bed system can also have a discrete and nonintrusive power cable configuration. In other words, only one cable can extend from the bed and plug into an external power source, such as a wall outlet in a bedroom. The cable can transmit power to various components of the bed system, including the wired charging ports in the pockets and the induction chargers in the side rails of the foundation. For example, cables can connect the charging ports and the induction chargers to a port in the bed system. Another cable can run from the port of the bed system to the wall outlet or other external power source to supply power to the components of the bed system. Since only one cable connects to the wall outlet to supply power to all the components of the bed system, other wall outlets and/or external power sources remain free to be used for supplying power to other components, such as nightstand devices and lights in the bedroom.

Moreover, the bed system can have a strong and durable design, engineered using high quality textiles, fine hardwoods, durable leather, and other materials that make the bed system sturdy. The bed system can also have accented tailoring and layering of materials to provide an aesthetically pleasing appearance. For example, the pockets can be made with a same material as the side rails of the foundation so that the pockets blend in with the side rails and are unobtrusive. This provides an aesthetically pleasing appearance of the bed system. As another example, the charging ports can be housed in a more rigid structure such as a charging port housing inside each of the pockets. The charging port housing can maintain cables and other wiring that may be used to provide power to the charging ports. The charging port housing can thus protect the cables and other wiring from being moved around or damaged when items are placed in and pulled out of the pockets.

Furthermore, while designed to support sleep needs for users of any age, the disclosed features and techniques of the bed system can also satisfy needs of a discrete aging population. Thus, the disclosed techniques can provide unique and dynamic abilities to adapt to any user of the bed system, no matter their needs.

The details of one or more implementations are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims.

Like reference symbols in the various drawings indicate like elements.

This document generally relates to a bed system storage pockets with device charging capabilities. The bed system can include a foundation having first and second side rails. Each of the side rails can include a pocket for storing items. Each of the pockets can also include wired charging capabilities and wireless charging capabilities. For example, a pocket can include USB and USB-C charging ports. A user of the bed system can plug in any type of device into either of the charging ports to charge their device. As another example, the pocket can include inductive charging. An induction charger can be integrated into the side rail parallel to a portion of the pocket where the user can place their device. When the device is placed inside the pocket, the device can be wirelessly charged via inductive charging. The pocket can also include a smaller, inner pocket, which can be configured to hold smaller items, including but not limited to smartphones, mobile phones, wearable devices, headphones, glasses, and/or remotes. In some implementations, the induction charger can be integrated into the side rail parallel to a midpoint of the smaller, inner pocket. Therefore, when a device is placed inside the smaller, inner pocket, the device can be automatically charged via induction charging.

Referring to the figures,depicts an example bed system. The bed systemcan include features that provide an improved sleep experience for a user of the bed system, including users having different age, conditions, demographics, and/or preferences.

The bed systemcan include a headboard, foundation, and mattress. The mattresscan be sized for one user, such as a twin mattress. The mattresscan also be sized for two users, such as a full, queen, king, and/or California king mattress. As illustrated in, the mattresscan be a king mattress having a split top portion and a joined bottom portion. The mattresscan be an air mattress or other suitable mattress. The mattresscan also be articulable or stationary.

The headboardcan include a main headboard portionand wingsA andB. The wingsA andB can extend a length along lateral edges of the mattress. In some implementations, the length can be 5 to 20 inches. In some implementations, the length can be 13 inches. For example, the wingsA andB can extend to a length along the lateral edges of the mattressthat includes a head portion of the mattresswhere the user may place their head on a pillow. As a result, the wingsA andB can act as a barrier to some noises that may exist in a surrounding sleep environment.

The headboardcan include features for improving sleep experiences of the user of the bed system. For example, the headboardcan include speakersA andB, microphonesA-N, lightsA-N, docksA andB, reading lightsA andB, and remotesA andB. The speakersA andB can be integrated into the wingsA andB, respectively. The speakersA andB can be configured to play white and/or pink noise to reduce and/or cancel noise in the surrounding sleep environment. The user can connect one or more user devices (e.g. mobile phone, tablet, PC, or other computer) or another audio input to the speakersA andB (e.g., Bluetooth connection) to control audio that is played through the speakersA andB.

The microphonesA andB can be integrated into the wingsA andB, respectively. Additional microphones can also be integrated into other portions of the bed system. For example, the microphoneN can be integrated into a midpoint of the headboard. Additional microphones can be integrated into the headboardfor each respective user/side of the mattress. The microphonesA-N can be configured to detect noise in the surrounding sleep environment (such as snore or breathing sounds of one or both users, external noises, etc.). Based on the detected noise, the bed system(e.g., a bed controller, such as controllerin) can generate an inverse sound wave to play through the speakersA andB to reduce and/or cancel the detected noise. As a result, the user of the bed systemcan experience improved sleep quality undisturbed by noises in the surrounding sleep environment (e.g., snore or breathing sounds of one or both users, external noises, etc.).

The lightsA-N can be integrated into a back portion of the headboard. The lightsA-N, for example, can be recessed into the back portion of the headboardand configured to provide ambient lighting that supports the user's circadian rhythm with wake and sleep routines.

The docksA andB can be integrated into the wingsA andB, respectively. The docksA andB can house components such as the reading lightsA andB, respectively, and the remotesA andB, respectively. These components can be kept in easy to access locations. In some embodiments, the user of the bed systemcan access either of the reading lightsA andB and/or the remotesA andB regardless of whether the user is laying down, sitting up, or otherwise inclined on the mattress. The reading lightsA andB can extend out from the respective docksA andB and be tilted in a desired direction of the user. The user can also adjust the reading lightsA andB color and intensity based on their particular needs and preferences. The remotesA andB can be used by the user to adjust their respective side of the bed system. For example, the remotesA andB can be used to adjust audio (e.g., volume level, turning audio on or off, setting a timer to automatically turn off the audio, etc.) that is played through the speakersA andB.

The foundationincludes side railsA andB. PocketsA andB (pocketB is not depicted in) can be integrated into the side railsA andB, respectively. The pocketsA andB can be storage pockets for holding objects including but not limited to mobile devices (e.g., laptops, tablets, mobile phones, smart phones, etc.), books, magazines, and other items. The pocketsA andB can include integrated inductive charging capabilities to charge one or more of the mobile devices placed therein. The pocketsA andB can also include charging ports to provide wired charging of the mobile devices. The charging ports can include USB and USB-C ports. The pocketsA andB can be integrated into portions of the side railsA andB that are easy to reach by the user of the bed system, regardless of whether the user is laying down, sitting up, or inclined to another position on the mattress.

Moreover, platesA andB (plateB is not depicted in) can be removably attached to a portion of the side railsA andB, respectively, that is aligned with and above the pocketsA andB, respectively. The platesA andB can cover holes that are integrated into the side railsA andB and configured to receive and support side rail accessories. The side rail accessories (not shown in) can include tabletops and handrails, which can improve functionality of the bed systemand assist the user of the bed systemto get in and out of bed. The platesA andB can provide an aesthetically pleasing appearance of the foundationwhen side rail accessories are not attached to the side railsA andB. When the side rail accessories are attached to either of the side railsA andB, the corresponding plateA orB can be removed so that the holes are exposed to receive supports of the side rail accessories.

depicts a first embodiment of the pocketon the side railA of the bed system.depicts a second embodiment of the pocketon the side railA of the bed system.depicts a third embodiment of the pocketon the side railA of the bed system. Referring to, as described herein, the pocketcan be integrated into an exterior side of each of the side railsA andB, where the side railsA andB are opposite each other. The pocketscan be sewn into an upholstery fabric of each of the side railsA andB. In some implementations, the pocketscan be attached to the side railsA andB using hook and loop fasteners. The pocketscan provide easy access to a user's devices and other items throughout the night and while the user is in the bed system.

The pocketcan be positioned at a location along the side railA that is closer to a head of the bed systemthan a foot end of the bed system. For example, the pocketcan be positioned within a range of 400-1000 mm from the head end of the bed system. As a result, the pocketcan be easily reached by a user of the bed system, regardless of whether the user is laying in a flat position or in another position in the bed system(e.g., sitting up, inclined in some way, etc.).

The pocketcan include an outer panelmade of a same flexible material (e.g. a fabric) as the side railA. As a result, the pocketcan blend in with the side railfor an aesthetically pleasing appearance. The pocketcan also include some flexibility to expand when larger items, such as thick magazines or books, are placed inside the pocket. Otherwise, the pocketmaterial can have a lining so that the outer panelis thicker and more rigid than a thin piece of upholstery fabric. Therefore, the pocketcan maintain its shape when items are placed therein.

The outer panelcan define a large cavityof the pocket, which can hold items that are placed inside the pocket. In some implementations, the pocketcan have a length of 16 inches. The pocketcan have a length of one or more other sizes and/or ranges, such as any length ranging from 10 to 20 inches. Large items, such as books, magazines, laptops, and/or tablets can be stored in the pocket.

An inner pocketcan be defined in the cavityof the pocket. Therefore, the inner pocketcan be smaller than the pocketand positioned inside the pocket. The inner pocketcan be positioned at a lateral edge of the pocketand can extend a distance towards a midpoint of the pocket. In some implementations, the inner pocketcan be positioned adjacent to the pocketalong the side railA. The inner pocketcan then be integrated into the side railA similarly to the pocket.

The inner pocketcan be sized to fit smaller items, such as smartphones, cellphones, wearable devices, remotes, headphones, and/or glasses. In some implementations, the inner pocketcan have a length of 5 inches. The inner pocketcan also have a length of one or more other sizes and/or ranges, such as any length ranging from 3 to 10 inches. The inner pocketcan also have a stretch tolerance of approximately ⅛ inch in each dimension (length, width, and height) to accommodate for development of larger smartphones and other mobile devices. Moreover, the user can place items inside the pocketin front of the inner pocket, regardless of whether the inner pocketis holding an item, such as a mobile phone. As a result, both pockets can be used at the same time.

In some implementations, the inner pocketcan be made of a different material than at least one of the side railA and the pocket. For example, as shown in, the inner pocketis made of a more rigid, leather-like material while the outer panelof the pocketis made of the same flexible upholstery material of the side railA. Sometimes, the inner pocketcan be made of a same material as at least one of the side railA and the pocket. For example, as shown in, the inner pocketis made of the same flexible upholstery material as both the outer paneland the side railA. In some implementations, the inner pocketcan be made of a fabric material, leather, vinyl, and/or plastic.

A charging port housingcan also be included in the cavityof the pocket. The charging port housingcan be positioned adjacent to the inner pocket. The charging port housingcan be positioned along an edge of the inner pocketthat is proximate a midpoint of the pocket. In some implementations, the charging port housingcan be mounted in the inner pocketadjacent an inner surface of the inner pocket. Sometimes, the charging port housingcan be positioned inside the inner pocket.

The charging port housingcan be a rigid structure that includes one or more charging ports, such as a USB port and a USB-C port, for wired charging of devices placed in the pocketand/or around the bed system. The charging port housingcan be made of a plastic material.

Cables can be run from the charging ports of the charging port housingto a power supply of the bed system(not depicted). The power supply can provide power to various components of the bed system. For example, the USB and/or USB-C ports in the charging port housingcan be in wired communication with the power supply to receive power for charging devices placed in the pocket, the inner pocket, and/or anywhere near the bed system. The power supply can also connect to an outlet in a bedroom environment via wire. For example, a single cable can run from the power supply of the bed systemto an external power supply, such as a wall outlet in the bedroom. Accordingly, the bed systemcan be powered by a single cable connected to an external power supply instead of requiring separate cables for various components of the bed systemconnecting to external power supplies, thereby freeing up the external power supplies to be used for other devices, such as nightstand devices and lights in the bedroom environment.